DE19946438C1 - Structure for electrical contacting of a valve - Google Patents

Abstract

A structure for the electrical contacting of an electrical valve (1), in particular a switching or pressure control valve for automatic transmissions of motor vehicles, is equipped with a contact spring element (12) arranged outside the valve housing (2). In the assembled state, the contact spring element (12) acts on an exposed mating contact element of a wiring element (9) under spring pressure. For this purpose, the contact spring element (12) has a pressure section (12.4) with a round contact surface.

Description

The invention relates to a structure for electrical contact animals of an electric valve, in particular switching or Pressure control valve for automatic transmissions of motor vehicles, with an electrical wiring element, in which the electrical valve with arranged outside the valve housing Neten contact spring elements is equipped, which in the mon tated state exposed mating contact elements of the ver Apply wire element under spring pressure.

In an automatic transmission there are hydraulic devices controlled by electric valves. Since the valves first integrated into the gearbox during final assembly their attachment usually by means of plug fastenings are provided at a suitable location within the transmission.

With such a construction, there is a difficulty in a safe and long-term stable electrical contact of the electric valve. The requirements for the contact security is expressed in practice high because the gearbox has extreme environmental conditions (Temperatures between -40 ° C and 140 ° C, vibration acceleration up to 33 g) and on the other hand (due to ho hen repair costs and possibly endangering people in In case of failure) highest reliability requirements are to be observed.

Another aspect of contacting the electri valve is closely related, the Rea lization of the electrical supply lines for the electrical Valve. There will be inexpensive supply concepts  aimed for an optimal unbundling and arrangement allow individual conductors within the transmission.

In the German patent application DE 42 33 783 A1 a Mag netventil described that when inserted into a fastener supply element via an immersion contact with one end a wiring running in the fastener elements is connected. The wiring element is on its other end with a pin in a connector Connection, which is at the top of the fastener is realized. The entire structure is complex and also the immersion contact does not always meet that in the pra xis requirements for contact security.

In the German patent application DE 43 24 781 A1 a white teres pluggable solenoid valve described. The on the Electrical on the outside of the valve body conclusions are designed as spring contacts. The electrical Contact is made using an orien in the direction of insertion Tiert contact pin of the spring element, which with its Front side under defined pressure on a counter contact presses on.

In the closest prior art German published application DE 197 25 289 A1 is an elect Raw hydraulic pressure control valve described, which in egg ner opening of a holding plate is anchored. For electrical Contacting the valve is provided by a circuit board adjacent to the hydraulic valve on the holding plate he stretches and from above through Kon attached to the valve body clock spring elements is contacted.

In the German patent DE 38 33 474 C2 a Ven tilblock for a slip-controlled hydraulic brake system described. A trace carrier with an integral  Ring seal extends into the interior of the valve body. There is a contact for the valve coil Contact spring with a curved contact area in contact with an exposed conductor track of the conductor carrier.

The invention has for its object a structure for electrical contact of an electrical valve create a permanent high level of contact guaranteed security and the use of inexpensive accessories concepts.

This object is solved by the features of claim 1.

Through the formed in the form of an arcuate strip Contact face becomes a low-wear contact point reali siert, whereby in particular the counter-contact element despite the mechanical and thermal stresses over his life sustained minimal damage. According to the invention have the contact spring element and the counter contact ment both tinned contact and counter contact surfaces. With This pair of materials gave the best results in tests regarding the mechanical and electrical contacts preserved. The required contact quality can half for a sufficiently long period (lifespan of the Transmission) are retained. Because of the low Wear and tear in the area of the contact point enabled and he Intended use of a flexible ladder plate is an inexpensive contact of the electri reached valve, which then turns out to be particularly favorable proves if, as part of an overall gearbox internal Connection concept for further mechatronic components (Ak gates, sensors, control electronics, etc.) by means of the flexible len circuit board are electrically connected.  

With a radius of curvature of the round contact surface of about 1.2 to 1.7 mm are particularly good contact properties ten reached.

A convenient area for those on the mating contact element The spring force exerted is between 12 and 15 N. One in the The force lying in the area is on the one hand for a safe Contact is large enough and still leads not relevant damage to the mating contact element.

By structuring the contact surface and / or by Provision of interlocking protruding over the contact surface  can cause a frictional movement of the contact surface on the Counter bearing surface can be effectively prevented.

Further advantageous embodiments of the invention are in specified in the subclaims.

The invention is illustrated below with the aid of an embodiment game described with reference to the drawing; in this shows:

Figure 1 is a schematic sectional view of an electromagnet valve used in a mounting body with a flexible circuit board contacting contact spring element.

Fig. 2A is a longitudinal sectional view of a relation to the contact shown in Figure 1 spring element slightly converted further contact spring element according to the invention.

FIG. 2B is a side view of the contact spring element shown in FIG. 2A; and

Fig. 2C shows a detail of Fig. 2B.

According to Fig. 1, a solenoid valve 1 has a cylindricity rule valve body 2 which is coupled via a not further illustrates asked plug fastening attachment in the bottom region with egg nem fastening body 3 of a building located in the transmission section. In the solenoid valve 1 (also not shown) an axially oriented solenoid coil is provided, the coil hole of which is penetrated by a Magnetan ker. The magnet armature is coupled in terms of movement to a piston element 4 , which leaves the valve body 2 on the bo side and is accommodated in a cylinder space 5 of the fastening body 3 in a sealingly longitudinally displaceable manner. The piston element 4 and the cylinder chamber 5 define a pressure chamber 7 , the tightness of which is ensured by ring seals 6.1 and 6.2 . The pressure chamber 7 is filled with a pressure fluid and is connected via pressure fluid channels to a hydraulically actuated gear shift mechanism (not shown).

A carrier element 8 made of plastic extends on the upper side of the fastening body 3 . This, in turn, carries a flexible printed circuit board 9 on its upper side. The flexible printed circuit board 9 realizes an integral electrical wiring element, via which a plurality of further electronic or electromechanical assemblies (e.g., transmission control unit, actuators, sensors) distributed within the transmission are electrically connected to one another. The carrier element 8 serves to support and defined routing of the flexible printed circuit board 9 in the transmission interior.

The carrier element 8 is optional, ie the flexible printed circuit board 9 can also rest directly on the top of the fastening body 3 .

A contact housing 10 made of plastic is attached to the outer wall of the valve body 2 . The contact housing 10 has a ceiling section 10.1 and a side wall 10.2 . The circumferential wall of the valve body 2, the ceiling portion of the side wall 10.1 and 10.2 of the contact housing 10 define ei NEN contact chamber 11 in which the bottom side the flexible Lei terplatte 9 protrudes.

The contact space 11 is not closed oil-tight in the foot area, so that penetration / leakage of gear oil into / out of the contact space 11 is possible. However, the side wall 10.2 realizes effective protection against the penetration of metal chips into the contact space 11 .

In the contact space 11 , a contact spring element 12 is brought under. The contact spring element 12 is anchored with an upper section (not visible) in the ceiling section 10.1 of the contact housing 10 . The upper portion of the con tact spring element 12 is also in a manner not shown Darge with an electrical implementation in connec tion, which extends from the ceiling section 10.1 through the wall of the valve body 2 and the Kontaktfe derelement 12 electrically connects to the solenoid.

At the upper mounting portion of the contact spring member 12, an angle section 12.1 adjoins. The two legs of the angular section 12.1 are oriented at 90 ° to each other and lie with their outer surface on the Innenwan extension of the contact housing 10 in the transition region from the Dec kenabschnitt 10.1 to the side wall 10.2 .

A circular segment section 12.2 adjoins the angular section 12.1 of the contact spring element 12 . The Krei ssegmentabschnitt 12.2 extends in the shown here biased state almost over 180 ° and passes by means of a bend in a ver in the axial direction of the valve 1 transition section 12.3 . The lower end of the contact spring element 12 is realized by an arcuate or skid-shaped pressure section 12.4 .

The operation of the contact spring element 12 is as follows:

When the solenoid valve 1 is inserted into the fastening body 3 , the outer surface of the arcuate pressure section 12.4 of the contact spring element 12 comes into contact with the surface of the flexible printed circuit board 9 . Here, the circular segment section 12.2 is deformed or compressed by a given design path, whereby a corresponding spring force is generated according to Hook's law. The spring force can be exactly specified by choice of material and dimensioning of the contact spring 12 taking into account the exact construction of the solenoid valve 1 and is 12 to 15 N, preferably 14 N. It has been shown that such a pressing force in combination with the arcuate pressing section according to the invention 12.4 is optimal, on the one hand to guarantee safe electrical contact even when strong vibrations occur and, on the other hand, to avoid damage to the flexible printed circuit board in the contact area over time. It is crucial that the outer surface of the bo gene-shaped pressure section 12.4 in the area of their abutment against the mating contact element has a rounded, edge-free run.

As a counter-contact element on the z. B. from Cu existing conductor a metallization (contact pad) made of tin is introduced. Excellent mechanical and electrical contacting properties are achieved with a tin contact pad and a tinned outer surface (contact surface) of the pressure section 12.4 .

The contact surface of the pressure section 12.4 can be provided with a slight embossing or structuring, which increases the positional stability of the pressure section 12.4 on the counter contact element.

In FIGS. 2A and 2B is a contact spring element 12 'Darge represents that of the example shown in Fig. 1 Kontaktfederele element 12 only in the upper range (angle section 12.1) by addition of a less than 45 ° relative to the axial direction sloping slope portion 12.5 is' differs . The contact spring element 12 'has a thickness D of 0.4 mm and a total length L of 25.2 mm in the relaxed state. The radius of the circular segment section 12.2 'is 4 mm and merges into the transition section 12.3 ' at an angle of 60 °.

The radius R1 of the arcuate pressure section 12.4 'be 1.4 mm and is preferably in a range between 1.2 and 1.7 mm. The arcuate course of the pressure section 12.4 'can also include an angle of 60 °. A dimension L1 = 14.5 mm can be provided from the beginning of the circular segment section 12.2 'to the vertex of the pressing section 12.4 '.

Fig. 2B shows that the contact spring member 12 may include 'in the region of the pressing 12.4' a smaller width than in the remaining region. The width B of the pressure section 12.4 '(and the contact surface 14 ') is z. B. 4 mm.

Fig. 2C shows the lower part of the pressing portion 12.4 'with the contact surface 14' in detail. The contact surface 14 'is smooth and has on its side edges projecting hooks or claws 13.1 ', 13.2 'which dig somewhat into the counter contact surface (not shown) and prevent the contact surface 14 ' from sliding on the counter contact surface.

The contact spring element 12 , 12 'can be formed from any suitable metal or any suitable metal alloy with good electrical conductivity and good permanently elastic properties. A suitable choice of material is realized by the alloys CuSn6 and CuNi9Sn2.

Claims (7)

1. Structure for electrically contacting an electrical valve ( 1 ), in particular switching or pressure control valve for automatic transmissions of motor vehicles, with an electrical wiring element ( 9 ), in which

• - The electric valve ( 1 ) is equipped with at least one contact spring element ( 12 , 12 ') arranged outside the valve housing ( 2 ), which acts on an exposed mating contact element of the wiring element ( 9 ) under spring pressure in the assembled state,

characterized by

• - That the contact spring element ( 12 , 12 ') has a pressure section ( 12.4 , 12.4 ') with a contact surface ( 14 ') designed as an arcuate strip,
• - That the wiring element is a flexible circuit board ( 9 ), and
• - That the pressure section ( 12.4 , 12.4 ') has a tin-plated contact surface ( 14 ') and the counter-contact element has a tin-plated counter-contact surface.

2. Structure according to claim 1, characterized in

• - That the arcuate contact surface ( 14 ') has a radius of about 1.2 to 1.7 mm.

3. Structure according to claim 1 or 2, characterized in

• - That the spring force exerted on the counter-contact element is between 12 and 15 N.

4. Structure according to one of the preceding claims, characterized in

• - That the pressure section ( 12.4 , 12.4 ') has a width measured parallel to the arc axis of about 3 to 5 mm.

5. Structure according to one of the preceding claims, characterized in

• - That the contact surface ( 14 ') of the pressure section ( 12.4 , 12.4 ') is structured.

6. Structure according to one of the preceding claims, characterized in that

• - That protruding hooking members ( 13.1 ', 13.2 ') are formed on the pressure section ( 12.4 , 12.4 ') over the contact surface ( 14 ').

7. Structure according to one of the preceding claims, characterized in that

• - That the contact spring element ( 12 , 12 ') is formed from a copper-tin alloy or a copper-tin-nickel alloy.